Fuel cell components

ABSTRACT

A strip of fuel cell components ( 200 ) comprising: a plurality of fuel cell components ( 202 ) spaced apart in a first direction; an indexing structure ( 210 ) connected to the plurality of fuel cell components, the indexing structure configured to define the position of one of the plurality of fuel cell components in the first direction; wherein the indexing structure is made from a different material to the plurality of fuel cell components. A component transfer mechanism for transferring a fuel cell sub-component to a substrate, using a roller and transfer tape. A strip of fuel cell components with a sub-component which is rotatable about a pivot. An apparatus and a method for assembling a fuel cell by applying a sub-component to an underside of a strip moving on a conveyor.

CROSS-REFERENCE TO RELATED APPLICATIONS

This patent application is a Continuation of international patent application PCT/GB2013/0052904 filed Nov. 6, 2013, which claims priority to GB patent application 1220017.6 filed Nov. 7, 2012, and GB patent application 1313231.1 filed Jul. 24, 2013, the disclosures of which are incorporated by reference in their entirety.

The invention relates to the field of fuel cells, and to fuel cell components and a method of assembly of a fuel cell stack in particular.

Electrode or separator plates for fuel cells, that is, in the form of anode or cathode plates, need to meet stringent requirements to avoid or remove any contamination, and typically require a series of different processing steps to be applied before the plates can be assembled into a fuel cell stack. Various types of coatings and other surface treatments may be required. Given that volume production of fuel cell parts requires a large number of such plates to be handled in rapid succession, a solution that enables accurate, economical and reproducible preparation and assembly of fuel cells is required.

In accordance with a first aspect of the invention there is provided a strip of fuel cell components comprising:

-   -   a plurality of fuel cell components spaced apart in a first         direction;     -   an indexing structure connected to the plurality of fuel cell         components, the indexing structure configured to define the         position of one of the plurality of fuel cell components in the         first direction;     -   wherein the indexing structure comprises a different material to         the plurality of fuel cell components.

The indexing structure can enable the positioning of fuel cell components at build points within a fuel cell stack to be performed more easily, more reproducibly or more reliably. The provision of the indexing structure also allows the transfer of fuel cell subcomponents held on a carrier to a fuel cell plate to be performed more easily, more reproducibly or more reliably. The provision of an indexing structure of a different material allows for a fuel cell stack to be produced more cheaply as the indexing material need not be made from the same, typically expensive, material as fuel cell plates. Thus, the fuel cell components do not need to include means to index the strip as the indexing function is provided by the indexing structure of different material. Optionally, the indexing structure of different material solely provides the indexing function for the strip over at least part of the strip in the first direction.

The indexing structure may be releasably or severably connected to the plurality of fuel cell components. The releasably or severably connection of the indexing structure can assist in providing an indexing structure of a different material to the fuel cell plates.

The plurality of fuel cell components may comprise a plurality of fuel cell assemblies. A fuel cell assembly may comprise a fuel cell plate. The plurality of fuel cell components may comprise a first end plate, a plurality of fuel cell assemblies and a second end plate, in that order extending in the first direction. Providing end plates on the indexing material can further ease the assembly process of the fuel cell stack.

The indexing structure may comprise a plurality of indentations or holes for engaging with an indexor in order to define the position of one of the plurality of fuel cell components.

The indexing structure may be connected to the plurality of fuel cell components by at least one spot weld.

The indexing structure may comprise a lateral fold region between adjacent fuel cell components.

The indexing structure may comprise a plurality of electrically conductive tracks that are insulated from one another.

According to a further aspect of the invention there is a fuel cell stack comprising a folded strip of fuel cell components as defined above.

According to a further aspect of the invention there is provided a method of assembling a fuel cell stack, the method comprising:

-   -   indexing the strip of fuel cell components according to any         preceding claim in order to locate a fuel cell component at a         build position.

The method may further comprise removing the indexing structure from the fuel cell component at the build position.

The indexing structure may comprise a lateral fold region between adjacent fuel cell components. The method may further comprise folding the indexing structure at the lateral fold regions in order to locate a plurality of fuel cell components at the build position.

According to a further aspect of the invention there is provided a component transfer mechanism for transferring a fuel cell sub-component to a substrate, the component transfer mechanism comprising:

-   -   a rotatable roller; and     -   a transfer tape that passes around the roller and is held in         tension such that rotation of the roller results in movement of         the transfer tape, wherein the transfer tape defines an outer         surface configured to carry the fuel cell sub-component;     -   wherein the component transfer mechanism is movable relative to         the substrate in a first direction, which is transverse to a         plane of the substrate, between a component transfer position in         which the transfer tape on the roller is adjacent the substrate         and a raised position in which the transfer tape on the roller         is spaced apart from the substrate; and     -   wherein the rotatable roller is configured to be rotated such         that the sub-component on the transfer tape is located in         between the roller and the substrate when the component transfer         mechanism is in the component transfer position.

The rotatable roller may be configured to be rotated at the same time that the component transfer mechanism is moved from the raised position to the component transfer position.

The component transfer mechanism may be movable relative to the substrate in a second direction that is parallel to a longitudinal axis of the substrate, which can progressively lay down the sub-component on the substrate.

The speed of the transfer tape around the roller may be faster than the speed of the substrate relative to the component transfer mechanism in the second direction in order to provide relative motion between the sub-component and the strip in the second direction.

The roller may have a radius that is sufficiently small in order to cause a transverse edge of the fuel cell sub-component to be detached from the transfer tape as it passes around the roller.

The substrate may comprise a strip of fuel cell components. The fuel cell sub-component may comprises a laminate layer comprising one or more of a gas diffusion layer, a first layer of catalyst, an electrode membrane and a second layer of catalyst. The substrate may comprise a gasket with an aperture, into which the laminate layer is to be placed.

According to a further aspect of the invention there is provided a method of transferring a fuel cell sub-component to a substrate using a component transfer mechanism, the component transfer mechanism comprising:

-   -   a rotatable roller; and     -   a transfer tape that passes around the roller and is held in         tension such that rotation of the roller results in movement of         the transfer tape, wherein the transfer tape defines an outer         surface configured to carry the fuel cell sub-component;

the method comprising:

-   -   moving the component transfer mechanism relative to the         substrate in a first direction, which is transverse to a plane         of the substrate, between a component transfer position in which         the transfer tape on the roller is adjacent the substrate and a         raised position in which the transfer tape on the roller is         spaced apart from the substrate; and     -   rotating the rotatable roller such that the sub-component on the         transfer tape is located in between the roller and the substrate         when the component transfer mechanism is in the component         transfer position.

According to a further aspect of the invention there is provided a strip of fuel cell components comprising a first sub-component that is rotatably connected to a second sub-component about a pivot, wherein the first sub-component is movable about the pivot between:

-   -   a first position that is parallel with a plane of the strip;     -   a second position that is out of the plane of the strip; and     -   a third position that is parallel with the plane of the strip         and is different to the first position.

The first sub-component may be adjacent to the second sub-component in the plane of the strip in the first position. The first sub-component may overly the second sub-component in the third position.

The strip of fuel cell components may further comprise a flexible joining region between a first transverse edge of the first sub-component and the second sub-component. The flexible joining region may be configured to provide the pivot.

The strip of fuel cell components may further comprise a severable joining region associated with a second transverse edge of the first sub-component. The severable joining region may be configured to releasably attach the first sub-component to a different second sub-component.

According to a further aspect of the invention there is provided a method of assembling a fuel cell from a strip of fuel cell components, the strip of fuel cell components comprising a first sub-component that is rotatably connected to a second sub-component about a pivot, the method comprising:

-   -   applying a first force to the first sub-component in a first         direction that is transverse to the plane of the strip in order         to move it from a first position that is parallel with a plane         of the strip to a second position that is out of the plane of         the strip; and     -   applying a second force to the first sub-component in a second         direction that is parallel to the plane of the strip in order to         move the first sub-component from the second position to a third         position that is parallel with the plane of the strip and is         different to the first position.

According to a further aspect of the invention there is provided an apparatus for assembling a fuel cell from a strip of fuel cell components, the apparatus comprising:

-   -   a first force applicator configured to apply a first force to         the first sub-component in a first direction that is transverse         to the plane of the strip in order to move it from a first         position that is parallel with a plane of the strip to a second         position that is out of the plane of the strip; and     -   a second force applicator configured to apply a second force to         the first sub-component in a second direction that is parallel         to the plane of the strip in order to move the first         sub-component from the second position to a third position that         is parallel with the plane of the strip and is different to the         first position.

The apparatus may further comprise a separator configured to separate a second transverse edge of the first sub-component from a neighbouring second sub-component.

The first force applicator may be a pusher. The second force applicator may be a roller.

According to a further aspect of the invention there is provided an apparatus for assembling a fuel cell comprising:

-   -   a conveyor for moving a strip of fuel cell components in a first         direction that is parallel to a longitudinal axis of the strip         of fuel cell components in order to locate a sub-component         receiving portion of the strip of fuel cell components at a         build point;     -   a component application mechanism for applying a sub-component         to an underside of the sub-component receiving portion of the         strip of fuel cell components at the build-point.

The component application mechanism may comprise a pusher configured to move the sub-component from a first position that is spaced apart from the strip of fuel cell components to a second position in which the sub-component is in contact with an adhesive surface on the underside of the strip of fuel cell components.

The apparatus may comprise a magazine for receiving a plurality of sub-components. The component application mechanism may be configured to apply a force to a bottom sub-component in the magazine in order to translate a top sub-component in the magazine to the second position.

The component application mechanism may be configured to apply a force to a sub-component that is located in a pocketed tape in order to translate the sub-component to the second position. The component application mechanism may comprise a pusher and a mechanism for laterally indexing the pocketed tape.

The apparatus may further comprise a support block that is movable between a first position that is spaced apart from an upper surface of the strip of fuel cell components, and a second position that is adjacent to the upper surface of the strip of fuel cell components, such that in the second position the support block is configured to prevent the strip of fuel cell components from moving as the sub-component is applied to the underside of the strip of fuel cell components.

According to a further aspect of the invention there is provided a method of assembling a fuel cell comprising:

-   -   moving a strip of fuel cell components in a first direction that         is parallel to a longitudinal axis of the strip of fuel cell         components; and     -   applying a sub-component to an underside of the strip of fuel         cell components.

Another strip of fuel cell components is also disclosed. The strip comprises:

-   -   a plurality of fuel cell components spaced apart in a first         direction, the plurality of fuel cell components comprising a         first surface;     -   a support structure connected to the plurality of fuel cell         components, the support structure comprising two lateral fold         regions between adjacent fuel cell components such that the         support structure is foldable in order for the first surfaces of         the plurality of fuel cell components to face in the same         direction when folded.

Each of the plurality of fuel cell components may be considered to comprise a common first surface. The first surfaces of the plurality of fuel cell components may be on a first surface of the strip.

The two lateral fold regions of the support structure between adjacent fuel cell components may ensure that the first surfaces of the plurality of adjacent fuel cell components to face in the same direction when folded.

The provision of the support structure that enables all of the cells to face in the same direction when folded provides a simplification for the method of manufacture of the fuel cell. Separate positioning of individual fuel cell components within the stack can be avoided.

The fuel cell components may comprise one or more of a gas diffusion layer or a membrane electrode assembly.

The support structure may be releasably or severably connected to the plurality of fuel cell components. The provision of a releasable or severable support material allows for a more efficient method of manufacture, as the support can be produced using a cheaper, sacrificial material and need not be made from the same material as the fuel cell.

The fuel cell components may be substantially planar.

The plurality of fuel cell components may comprise a plurality of fuel cell assemblies and a plurality of spacing components. A spacing component may be provided between adjacent fuel cell components. Alternatively, the plurality of fuel cell components may comprise a plurality of fuel cell assemblies and a plurality of voids. A void may be provided between adjacent fuel cell components. The spacing components, voids and fuel cell assemblies may be of a similar length in the first direction.

The plurality of fuel cell components may comprise a plurality of fuel cell assemblies. The support structure may comprise two lateral fold regions between adjacent fuel cell assemblies.

The plurality of fuel cell components may each comprise a second surface, which opposes the first surface. The support structure may be foldable such that the first surface of a fuel cell component faces the second surface of an adjacent fuel cell component when the strip is folded.

The support structure may be connected to both sides of the plurality of fuel cell components. Alternatively, the support structure may be connected to only one side of the plurality of fuel cell components.

The support structure may comprise an electrical connection to a fuel cell component to which it is connected. The support structure may comprise an indexing structure.

The plurality of fuel cell components may comprise a first end plate, a plurality of fuel cell assemblies and a second end plate, in that order, extending in the first direction.

The first surface of the first end plate may be an external face of a fuel cell stack. The first surface of the second end plate may be an internal face of a fuel cell stack. The second surface of the first end plate may be an internal face of a fuel cell stack. The second surface of the second end plate may be an external face of a fuel cell stack.

The support structure may comprise only one fold region between the first end plate and the plurality of fuel cell assemblies. The support structure may comprise only one fold region between the second end plate and the plurality of fuel cell assemblies.

There may be provided a device configured to form the strip of fuel cell components.

There is also disclosed a method of assembling a fuel cell stack, the method comprising:

-   -   folding a strip of fuel cell components according to any         preceding claim in order to locate a plurality of fuel cell         components at a build position in order to form a fuel cell         stack.

The method may further comprise removing at least a portion of a support structure from the plurality of fuel cell components at the build position. Removing at least a portion of the support structure from the plurality of fuel cell components at the build position may comprise leaving a portion of the support structure comprising an electrical connection connected to the plurality of fuel cell components.

There is also disclosed a method of assembling a fuel cell stack, the method comprising:

-   -   locating a first strip of partial fuel cell components over a         second strip of partial fuel cell components; and     -   fan folding the first and second strips of partial fuel cell         components together in order to assemble a fuel cell stack.

Such a method provides a simple and convenient way to assemble a fuel cell stack as separate positioning of individual fuel cell components within the stack can be avoided.

Fan folding the first and second strips of partial fuel cell components together may comprise locating a partial fuel cell component that is in a first region of the first strip adjacent to a partial fuel cell component that is in a corresponding region of the second strip in order to define a complete fuel cell. In this way, individual fuel cells can be reliably and consistently constructed within the fuel cell stack.

One or both of the strips of partial fuel cell components may comprise a support structure. Such support structures may have two lateral fold regions between adjacent partial fuel cell components. A spacing element may be located between the two lateral fold regions that are between adjacent partial fuel cell components. The step of fan folding the first and second strips of partial fuel cell components together may comprise causing the partial fuel cell components of the first strip and second strip to contact each other through the spacing element. Providing such spacing elements can provide for a simplified method of assembly as a partial fuel cell component in the first strip can be adjacent to a partial fuel cell component in the second strip on both sides when folded, and vice versa.

There is also disclosed a fuel cell stack comprising:

-   -   a first strip of partial fuel cell components; and     -   a second strip of partial fuel cell components;     -   wherein the first and second strips of partial fuel cell         components are located one over the other in a fan folded         orientation in order to define the fuel cell stack.

A partial fuel cell component that is in a first region of the first strip may be located adjacent to a partial fuel cell component that is in a corresponding region of the second strip in order to define a complete fuel cell.

The first strip of partial fuel cell components may comprise a support structure connected to the partial fuel cell components. Additionally or alternatively, the second strip of partial fuel cell components may comprise a support structure connected to the partial fuel cell components.

One or both of the support structures may comprise two lateral fold regions between adjacent partial fuel cell components. A spacing element may be located between the two lateral fold regions that are between adjacent partial fuel cell components. A spacing element may have an opening that is configured to allow components to contact each other through the thickness of the strip. In this way, a simplified arrangement of components on the strip can be used as the spacing elements can ensure that partial fuel cell components in the first strip are adjacent to a partial fuel cell component in the second strip on both sides when folded, and vice versa.

For example, one side of the partial fuel components in the first strip can be directly adjacent to the second strip, and the other side of the partial fuel components in the first strip can be exposed to the second strip through the opening in the spacing element.

The first and/or second strip of partial fuel cell components may comprise one or a plurality of electrically conductive tracks for providing an electrical connection to one or more of the fuel cells in the fuel cell stack from externally of the stack. The electrically conductive track may be associated with any support structure disclosed herein. The electrically conductive track or tracks may extend in a direction along the length of the strip. The plurality of electrically conductive tracks may each have a node for external connection at one end and may be connected to a fuel cell at the other end. Different electrically conductive tracks may be connected to different fuel cells in the fuel cell stack, and may be individually addressable by the associated nodes. The plurality of nodes may be located at the same end of the strip, optionally on an external connector frame.

The partial fuel cell components of the first strip and the second strip may together comprise one or more of: a first electrode; a membrane, a second electrode, a cathode gas diffusion layer (which collectively may be referred to as a four layer membrane electrode assembly), an indexing structure (which may comprise a first indexing structure and a second indexing structure), a shim, a gasket, an anode gas diffusion layer and a bipolar plate.

The partial fuel cell components of the first strip may comprise one or more of: a first electrode; a membrane, a second electrode, a cathode gas diffusion layer (which collectively may be referred to as a four layer membrane electrode assembly), a first indexing structure and a second indexing structure. The partial fuel cell components of the second strip may comprise one or more of: a shim, a gasket, an anode gas diffusion layer and a bipolar plate.

The second strip may comprise a current collector plate at one end and an external connector frame at the other end. A node that is electrically connected to the current collector plate may be provided on the external connector frame. The node may be for external connection to the fuel cell stack.

Embodiments of the present invention may be better understood with reference to the accompanying drawings, in which:

FIGS. 1a and 1b show a process for manufacturing a fuel cell;

FIG. 2 shows a schematic of a strip comprising a plurality of fuel cells;

FIG. 3 shows three side views of a schematic of a folded strip;

FIGS. 4a and 4b show a schematic of a strip and a carrier;

FIGS. 5a and 5b show a schematic of a strip and a case;

FIG. 6a shows a schematic of a portion of a fuel cell production line;

FIG. 6b shows an alternative schematic of the portion of the fuel cell production line of FIG. 6 a;

FIG. 6c shows a schematic of a portion of another fuel cell production line;

FIG. 6d shows an alternative schematic of the portion of the fuel cell production line of FIG. 6 a;

FIG. 7 shows a method of assembling a fuel cell stack;

FIG. 8 shows another method of assembling a fuel cell stack;

FIG. 9 shows a further method of assembling a fuel cell stack;

FIGS. 10a to 10e illustrate a strip of fuel cell components and apparatus for assembling a fuel cell from the strip;

FIGS. 11a to 11e illustrate schematically the operation of a component transfer mechanism for transferring a fuel cell sub-component to a substrate;

FIG. 12 shows a further method of transferring a fuel cell sub-component to a substrate using a component transfer mechanism;

FIG. 13 shows a method of assembling a fuel cell from a strip of fuel cell components; and

FIG. 14 shows a method of assembling a fuel cell.

FIGS. 1a and 1b show schematically a process 100 for manufacturing a fuel cell. FIG. 1 is used to describe how the provision of a support structure allows a fuel cell stack to be constructed from a strip of fuel cells that are aligned in the same direction when the strip is folded such that the fuel cells form a stack.

FIG. 1 is broken down into a number of occupied frames 102, 108, 112, 116, 120, 124. The occupied frames 102, 108, 112, 116, 120, 124 show successive operations for the formation of a fuel cell. The occupied frames 102, 108, 112, 116, 120, 124 are each separated from one another by empty frames 103, 109, 113, 117, 121. The empty frames will be discussed in further detail with relation to FIG. 2.

In each occupied frame 102, 108, 112, 116, 120, 124, the fuel cell is illustrated such that the cell has a left side edge 105 and a right side edge 107 in the plane of the cell. For clarity, equivalent features in the various occupied frames 102, 108, 112, 116, 120, 124 of FIG. 1 are only labelled in the frame in which they are first discussed.

In a first frame 102, a bipolar plate 104 is shown. The bipolar plate 104 may be a pressed plate. The bipolar plate 104 is substantially planar. The bipolar plate 104 has a weld point 106 adjacent to each of its corners. Two weld points 106 are positioned on the left side edge 105 of the bipolar plate 104 and two weld points 106 are positioned on the right side edge 107 of the bipolar plate 104. The weld points 106 are configured to be welded to a separate support structure such as an indexing track using a spot welding technique. Alternatively, the support structure may be configured to clip on to the ‘weld points’. As such, the term ‘weld point’ should be construed broadly to encompass any site configured to be severably or removably coupled with an additional structure. A “weld point” may also be referred to as a “connection point”.

In a second frame 108, the bipolar plate 104 has been welded to a left side indexing structure 110 a that runs along the length of the left side edge 105 of the bipolar plate 104 and to a right side indexing structure 110 b that runs along the length of the right side edge 107 of the bipolar plate 104 in a first direction. The first direction is generally parallel with the side edges 105, 107 of the bipolar plate 104 and an axial direction of the indexing structures 110 a, 110 b.

The left and right side indexing structures 110 a, 110 b are examples of support structures that may be used to couple multiple fuel cells together. In addition to the support capability, the indexing structures can provide the additional benefit of enabling alignment of the fuel cells and their components. The left side indexing structure 110 a is severably, or releasably, connected to the bipolar plate 104 at the weld points 106 on the left side edge 105 of the bipolar plate 104. The right side indexing structure 110 b is severably, or releasably, connected to the bipolar plate 104 at the weld points 106 on the right side edge 107 of the bipolar plate 104.

The indexing structures 110 a, 110 b are configured to define the position of one of the plurality of fuel cell components in the first direction. The indexing structure allows manufacturing equipment to track the position of fuel cell components more easily more reproducibly and/or more reliably, so that correct spacing between components can be maintained. In this way, the provision of the indexing structure allows for improved automated handling fuel cell plates by alleviating some of the difficulties associated with the positioning of individual plates within a fuel cell stack.

The indexing structures 110 a, 110 b comprise a plurality of indentations or holes for engaging with an indexor (not shown in the drawings) in order to define the position of one of the plurality of fuel cell components. The manufacturing equipment may comprise an electronic camera and image recognition software so as to identify the position of the indexing structures 110 a, 110 b and the relative position of fuel cell components, such as bipolar plates 104. Such an arrangement can provide for a cheaper, quicker and/or more accurate process for manufacturing a fuel cell or fuel cell stack.

In the example shown in FIG. 1, the indexing structures 110 a, 110 b may be used to provide automated recognition of the position of fuel cell components with reference to the support structure. The indexing material can therefore be used to simplify the construction of fuel cells, or to improve the performance of automated techniques that construct fuel cells. The use of an indexing structure in the improved formation of a fuel cell stack will be described further below with reference to FIG. 2.

The indexing structures 110 a, 110 b can be formed of a different type of material to the bipolar plate 104. That is, the indexing structures 110 a, 110 b is formed/made exclusively of (consists only of) a different type of material to the bipolar plate 104. For example, the indexing structures 110 a, 110 b may be formed of mild steel or polyethylene naphthalate (PEN). Providing the indexing structures 110 a, 110 b as a different type of material from the bipolar plate 104 can reduce the cost of materials used in the manufacture of the bipolar plate 104. Indeed, the additional cost of the extra indexing structures 110 a, 110 b may not be significant through suitable choice of materials. The indexing structures 110 a, 110 b may be made from a less costly material than the bipolar plate 104 as it can have less stringent requirements, such as electrical conductance characteristics.

Alternatively, it may be convenient in some applications for the left and right side indexing structures 110 a, 110 b to be the same as each other, or at least to be made of the same material as each other, in order to further reduce the complexity of manufacture.

In a third frame 112, an over-mold process is used to apply a liquid injection molding (LIM) seal 114 around the extremity of the bipolar plate 104. The over-mold process allows a polymer to be applied to a metal substrate that extends beyond the die of the mold whilst avoiding unwanted extrusion of the polymer seal material.

In a fourth frame 116, a die cut process is used to form a subgasket 118 and a lamination technique is used to apply the subgasket 118 to the bipolar plate 104.

In a fifth frame 120, an anode gas diffusion layer 122 is placed within the subgasket 118 on the surface of the bipolar plate 104 and bonded in place using a lamination technique. Welding, bonding or the use of a retaining means such as an adhesive are examples of bonding methods that may be suitable.

In a final, sixth frame 124, a four layer fuel cell membrane lamination 126 is applied and bonded over the anode gas diffusion layer and subgasket. The four layer cell membrane 126 comprises the following layers: a first electrode; a membrane, a second electrode; and a cathode gas diffusion layer. The arrangement of subcomponents illustrated in the sixth frame 124 is referred to as a fuel cell. Such a fuel cell can be positioned on top of other fuel cells to provide a fuel cell stack.

It will be appreciated from the description that follows that the fuel cell shown in the sixth frame 124 of FIG. 1 can be provided by more than one strip of partial fuel cell components.

FIG. 2 illustrates a strip 200 comprising three fuel cells 202 a, 202 b, 202 c similar to the one illustrated in the last frame of FIG. 1b . Three views of the strip 200 are illustrated: a top down view 201 (similar to the view in FIG. 1); an extended side-on view 203; and a folded side-on view 205.

From the top down view 201, it can be seen that the fuel cells 202 a, 202 b, 202 c are all severably welded to a left side support structure 210 a and a right side indexing structure 210 b. The left and right side indexing structures 210 a, 210 b are similar to those applied by the process illustrated in FIG. 1. The indexing structures 210 a, 210 b are an example of support structures. It will be appreciated that a support structure may be provided that does not comprise indexing material.

The strip 200 comprises a succession of occupied and empty frames. The occupied frames each comprise a fuel cell 202 a, 202 b, 202 c. The fuel cells 202 a, 202 b, 202 c consist of fuel cell components. The fuel cells 202 a, 202 b, 202 c are spaced apart in a first direction. The indexing structures 210 a, 210 b extend in the first direction and connect the plurality of fuel cell 202 a, 202 b, 202 c. The plurality of fuel cell 202 a, 202 b, 202 c comprise a first surface that faces in the same direction when the strip of fuel cells 202 a, 202 b, 202 c is laid flat.

The empty frames 204 a, 204 b do not comprise a fuel cell 202 a, 202 b, 202 c, but may be considered to comprise indexing structures 210 a, 210 b, as the indexing structures extend in the first direction adjacent to both the fuel cells 202 a, 202 b, 202 c and to voids that make up the empty frames 204 a, 204 b. The length of the indexing structures 210 a, 210 b in the occupied frames is similar to that of the indexing structures 210 a, 210 b in the empty frames 204 a, 204 b.

In the extended side-on view 203, an anode side of each of the fuel cells 202 a, 202 b, 202 c and a cathode side of each of the fuel cells 202 a, 202 b, 202 c can be seen on the respective first surfaces 206 and second surfaces 208 of the fuel cells 202 a, 202 b, 202 c. This arrangement of the fuel cells is different from the example shown in FIG. 1, in which both the anode and cathode gas diffusion layers are provided on a single side of the bipolar plate. It will be appreciated that the processes and strips of components described herein can be implemented irrespective of how each individual fuel cell is constructed.

Fold lines 212 are superimposed on the strip 200 as seen in the top down view 201 and the extended side-on view 203. The fold lines 212 are positioned at the intersection of the occupied and empty frames; the fold lines 212 represent lateral fold regions between the adjacent fuel cells 202 a, 202 b, 202 c and empty frames 204 a, 204 b. The indexing structures 210 a, 210 b comprise two lateral fold regions between adjacent fuel cells 202 a, 202 b, 202 c. The support structure 210 a, 210 b comprising two lateral fold regions 212 between adjacent fuel cell components 202 a, 202 b, 202 c means that the support structure is foldable such that the first surfaces of the plurality of fuel cell components face in the same direction when the strip 200 is folded.

In the folded side view 205, the strip 200 is fan folded so as to form a stack of cells. From the folded side view 205 it can be seen that by the provision of empty frames 204 a, 204 b between the fuel cells 202 a, 202 b, 202 c, the first surfaces 206 of the plurality of fuel cells 202 a, 202 b, 202 c face in the same direction when the indexing structure is folded. Similarly, second surfaces 208 of the fuel cells 202 a, 202 b, 202 c also face in the same direction when the indexing structure is folded. As the orientation of the anode and cathode sides of the cells is therefore the same for all of the plates, a simplified method of construction can be employed to form the stack as all of the plates can be easily aligned.

In some examples, the fuel cells 202 are connected to only one support or indexing structure 210 a, 210 b. That is, only one side of the cells 202 may be connected to a support or indexing structure. In some examples, a strip is provided in which each frame between two indexing structures 210 a, 210 b has a fuel cell 202. That is, initially there are no empty frames. The strip of fuel cells can then be separated into two strips, with each strip comprising one of the support structures 210 a, 210 b and alternate fuel cells 202. In this way, each of the two strips has alternate empty frames in the spaces that have been vacated by the fuel cells 202 that are part of the other strip.

FIG. 3 illustrates three side views of a folded strip 300. A fan folded side view 301 shows the same arrangement illustrated in the folded side view 205 of FIG. 2. A second view 303 shows the folded strip under compression, forming a fuel cell stack. A third view 305 shows the fuel cell stack secured with tie bars 306.

In the second view 303, a first end plate assembly 302 and a second end plate assembly 304 are provided. The first end plate assembly 302 is in contact with the first surface of the top fuel cell. The second end plate assembly 304 is in contact with the second surface of the bottom fuel cell. In addition to the features illustrated in the second view 303, insulator frames of material may be provided at the respective ends of the strip 300 to separate and provide electrical insulation between the fuel cells and the end plates 302, 304. The insulator frames may be provided by the support structure. That is, the support structure may be retained in the final fuel cell stack and extend, at the respective ends of the strip 300 of fuel cells, to form an insulating layer between the strip 300 and the end plates 302, 304. Alternatively, the insulator frames may be provided by nylon sheets that are connected to the support structures at weld points on the sheets.

In the second view 303, external compression is applied in a direction normal to the plane of the fuel cells of the stack in order for the seals and gaskets between the fuel cells to function correctly.

In the third view 305, tie bars 306 have been used to secure the stack in compression. The external compressive force is therefore no longer required. At this stage in the production of the fuel cell stack, the indexing structures can be removed. Alternatively, the indexing structures could be removed before or during compression. This removal can be achieved by, for example, melting or cutting the welds that link the fuel cells to the indexing structures. A laser trimming process may be employed to sever the welds that link the bipolar plates and the indexing strips. However, in some embodiments, some or all of the indexing material may be retained in the end product and not be severed from the fuel cells. The retained indexing material may be used to provide additional features to the cell, as will be apparent from the examples provided in FIGS. 4 and 5.

In some embodiments of the invention, a carrier may be employed to carry at least some subcomponents of a fuel cell. The use of carriers can simplify the manufacture of a fuel cell comprising multiple structures. Combinations of a carrier and indexing structures can further improve the reproducibility of component placement by automated systems and enable an increase in production speed.

FIGS. 4a and 4b illustrate a strip 400 a, 400 b of fuel cell subcomponents and a carrier 401 a, 401 b. The carrier 401 a, 401 b is laid over the strip 400 a, 400 b before the strip 401 a, 401 b is fan folded to form the fuel cell stack. In this way, the fuel cell stack alternately comprises, in a direction through the thickness of the fuel cell subcomponents, a region of the strip 400 a, 400 b and a region of the carrier 401 a, 401 b.

The strip 400 a, 400 b of fuel cell subcomponents is an example of a first strip of partial fuel cell components. The carrier 401 a, 401 b is an example of a second strip of partial fuel cell components. It will be appreciated from the description that follows that the strip 400 a, 400 b and carrier 401 a, 401 b can be located one over the other, and then fan folded together in order to assemble a fuel cell stack.

Two views of the strip 400 a, 400 b and carrier 401 a, 401 b are shown. In the view shown in FIG. 4a , four layer membrane electrode assemblies 402 a (similar to those of FIG. 1) are shown separate from the carrier 401 a. Also, anode gas diffusion layers 404 a are shown separate from the strip 400 a in FIG. 4a . In FIG. 4b , the four layer membrane electrode assemblies 402 b are laminated on to the carrier 401 b, and the anode gas diffusion layers (GDL) 404 b are laminated on to the strip 400 b. Other than these details, the structure of the carrier 401 a, 401 b and the strip 400 a, 400 b are similar in FIGS. 4a and 4b . The features of the carrier 401 b and the strip 400 b are discussed in further detail below with reference to FIG. 4 b.

The strip 400 b comprises a plurality of partial fuel cells 406, each partial fuel cell comprising a plurality of subcomponents including in this example a shim and gasket, an anode gas diffusion layer and a bipolar plate. The construction of the partial fuel cells 406 is similar to the fuel cells shown in the fifth frame of FIG. 1.

Spacing elements 408 are provided between the adjacent partial fuel cells 406. The spacing elements 408 are located between two lateral fold regions that are between adjacent partial fuel cells 406. That is, partial fuel cells 406 and spacing elements 408 alternate along the length of the strip. Each spacing element 408 has an opening that allows components to contact each other through the thickness of the strip. In this way, a simplified arrangement of components on the strip can be used as the spacing elements 408 can ensure that each partial fuel cell component in the strip 400 b is adjacent to the fuel cell components in the carrier 401 b, and vice versa.

In some embodiments, the spacing elements 408 define gaps or voids between partial fuel cells 406. That is, the spacing elements 408 may not comprise any components of a fuel cell. In other embodiments, including those for air-breathing fuel cell stacks, the spacing elements 408 may comprise a cathode shim together with a second cathode gasket (optionally provided with adhesive) that forms a seal when the strip 400 b is folded-up to define the fuel cell stack. That is, the spacing elements 408 may comprise components of a fuel cell, and therefore may be considered as a partial fuel cell component.

The spacing elements 408 have similar dimensions to the partial fuel cells 406 and may be formed from the same sheet of material as the plate/shim and gasket 400 a, 400 b, indexing structure or any fuel cell subcomponent. At least part of the spacing elements 408 and the partial fuel cells 406 may be made from a continuous laminated material that is profiled in form to define parts of both the spacing elements 408 and the partial fuel cells 406.

Each of the partial fuel cells 406 is connected to an adjacent spacing element 408 along a fold line at the intersection of the fuel cells 406 and spacing elements 408. Therefore, two fold lines are provided between adjacent fuel cell components. In some examples, the spacing elements can themselves comprise fuel cell components. In such examples, the spacing elements and the partial fuel cells do not comprise common components. As such, common components are not provided in adjacent frames of the strip.

The fold line may be considered to pass through a fold region 407. In this example, the fold region 407 is provided by cutting away the majority of material between the fuel cells 406 and spacing elements 408. The position of the fold region 407 may be located using indexing material (not shown) that can be provided on the strip 400 a, 400 b or carrier 401 a, 401 b and extend normal to the first direction along a length of the strip 400, 400 b. Two coupling portions 409 are provided between adjacent fuel cells 406 and spacing elements 408. The coupling portions 409 can be considered to perform the function of shims.

Alternatively, the fold region may comprise a region of weakened material joining the fuel cells 406 and spacing elements 408. Such a join, which may be referred to as a ‘living hinge’ can be designed to withstand repeated folding and unfolding steps, sufficient to subject a stack of plates to fan folding. The line of weakened material may be provided by a series of perforations.

The carrier 401 b comprises a four layer membrane electrode assembly 402 b, a first indexing structure 410 down a first side of the four layer membrane electrode assembly 402 b, and a second indexing structure 412 down a second side for the four layer membrane electrode assembly 402 b. It will be appreciated that either or both of the strip 400 a, 400 b and carrier 401 a, 401 b can be considered as providing the indexing structure.

A partial fuel cell component that is in a first region of the strip 400 b is located adjacent to a partial fuel cell component that is in a corresponding region of the carrier 401 b in order to define a complete fuel cell. That is, complete fuel cells are provided when the strip 400 b is located next to the carrier 401 b and fan folded to define a stack. The first region of the strip 400 b may be considered as components that are between adjacent fold lines (for example a fuel cell 406 in FIG. 4b ), or it may be considered as components that are either side of a fold line (for example a fuel cell 406 and a spacing element 408 in FIG. 4b ).

The membrane electrode assemblies (MEAs) 402 b are fixed in place on the carrier material and separated from other MEAs 402 b by voids 414. The voids 414 are examples of spacing elements. It will be appreciated that the voids 414 in the carrier 401 b do not necessarily have to align with the spacing elements 408 in the strip 400 b.

The indexing structures 410, 412 each comprise a plurality of electrically conductive tracks 416 that are insulated from one another. The electrically conductive tracks 416 are each in electrical contact with either anode or cathode side of a cell to facilitate either (i) monitoring of cell performance or (ii) provision of current collection. Each of the electrically conductive tracks 416 extend along a respective length of one of the indexing structures 410, 412. The electrically conductive tracks 416 can be used to draw off current from the fuel cells when they are assembled into a stack. It will be appreciated that in an alternative embodiment, one or more or all of the fuel cells could share a conductive track.

FIGS. 5a and 5b show a fuel cell case 502 a, 502 b and a strip 504 of fuel cells 506 with similarities to the structure formed by the combination of the strip and carrier in FIG. 4. In addition to the features of the strip and carrier of FIG. 4, the strip 504 of FIG. 5 comprises a current collector plate 514, an external connector frame 520 and an insulator frame 522. In this example, the base 502 a of the case comprises a first end plate and the top 502 b of the case comprises a second end plate.

A first insulating frame 508 of the strip 504 of fuel cells 506 has been placed in a base of the case 502 a. A fuel cell stack may be formed by folding the strip 504 of fuel cells 506, 507 along lateral fold lines 510 that separate the fuel cells 504 and empty frames 512. The empty frames 512 are examples of spacing elements. A lateral fold line 510 is provided at the extremities of each of the empty frames 512. Once the fuel cells 506, 507 are all within the base 502 a, a lid of the case 502 b may be placed on top of the folded fuel cells in order to complete the fuel cell stack.

The strip 504 of FIG. 5 differs from the strip shown in FIG. 4 in a number of ways. For example, a current collector plate 514 is provided on the first insulating frame of the strip 504 and an external connector frame is provided at the other end of the strip 504. The conductive plate 514 is insulated from the first end plate provided in the base 502 a of the case by the first insulating frame 508. The current collector plate 514 is coupled to a conductive track 516 that runs along a support structure 518 to the external connector frame 520 at the other end of the strip 502. The fuel cells 506 are also coupled to similar conductive tracks 516 for current monitoring. The conductive tracks 516 terminate at nodes 518 on the external connector frame 520. The current collector plate 514, conductive tracks 516 and nodes 518 may comprise a material such as copper. As can be seen from FIG. 5b , the nodes 518 are exposed for external connection when the stack is constructed.

The fuel cell 507 nearest to a portion of the strip 502 that will form the top of the stack may be referred to as the top fuel cell 507. The top fuel cell 507 is adjacent to an optional spacing element (empty frame) 512. The spacing element 512 is adjacent to an insulator frame 522 that comprises an electrically insulating material. The insulator frame 522 separates the lid 502 b, which forms a second end plate, from the top fuel cell 507 when the stack is folded. The insulator frame 522 is separated from the external connector frame 520 by an end spacing element 513. However, the function of the end spacing element 513 differs from that of the rest of the spacing elements 512; the lateral folds at the extremities of the end spacing element 513 are each folded 90 degrees with respect to the adjacent frames 520, 522. The end spacing element 513 allows the connector frame 520 to be positioned on the exterior of the second end plate that is built into the top of the case 502 b. The surface of the insulator frame 522 shown in FIG. 5a does not face in the same direction as the surface of the connector frame 520 when the strip is folded.

FIG. 5b illustrates a fan folded view of the strip 504 seen in FIG. 5a . The distance in the direction through the stack is exaggerated for clarity. The angle between adjacent fuel cells 506 and the carrier portions of empty frames 512 approaches 180 degrees (where the fuel cell thickness is small compared to its width) when the strip 504 is folded.

Pressure pads 524 may be provided on a surface of connector frame 520 that opposes the surface on which the conductive nodes 518 are provided. The pressure pads 524 can provide a pressure absorbing layer between the second end plate provided in the top 502 b of the case and the connector frame 520. The provision of the pressure pads 524 may prevent damage to the stack when a compressive force 526 is applied to the fuel cell stack and can offer compliance and maximise or increase contact between electrically conductive surfaces. The compressive force 526 is required to engage and seal via compression the cells and gaskets of the various cell cells 506, 507 within the stack and to enable final stack assembly, as is known in the art.

FIG. 6a shows an apparatus for assembling a fuel cell, which may be a portion of a production line 600 for a fuel cell stack 602. The production line 600 comprises a conveyor 604, which may be a conveyor belt, for moving a strip of fuel cell components in a first direction that is parallel to a longitudinal axis of the strip of fuel cell components in order to locate a sub-component receiving portion of the strip at a build point. Only the support structure 606 of the strip of fuel cell components is shown in the side view of FIG. 6a . The first direction is shown schematically in FIG. 6a with arrow 603, and is in the plane of the strip of fuel cell components as they pass through the apparatus. The first direction in this example is horizontal.

The conveyor 604 may have an indexor (not shown) that is configured to interact with indexing on the support structure 606 associated with a plurality of fuel cell as fuel cell subcomponents. The indexor can move the strip of fuel cell components in the first direction in order to locate the sub-component receiving portion of the strip at a build point. For example the conveyor 604 may only engage with side edges of the support structure 606. The support structure 606 comprises a number of frames.

The apparatus in this example further comprises a first component application mechanism (which may be referred to as a bottom application mechanism 608) and optionally a second component application mechanism (which may be referred to as a top application mechanism 610). The bottom application mechanism 608 is configured to apply sub-components/structures such as manifold seals to an underside of the sub-component receiving portion of the strip at the build-point. The top application mechanism 610 can place fuel cell subcomponents on the top of the strip of fuel cell components so as to form a complete fuel cell 612 in a frame of the support structure 606. It will be appreciated that in some examples only one application mechanism may be required.

In this example the bottom application mechanism 608 comprises a pusher 609 configured to move a sub-component 611 from a first position that is spaced apart from the strip of fuel cell components in a second direction to a second position in which the sub-component 611 is in contact with an adhesive surface (not shown) on the underside of the strip of fuel cell components. The second direction 605 is shown in FIG. 6a with arrow 605 and is transverse to the first direction 603.

In this example the bottom application mechanism 608 also comprises a magazine 611, in which is stacked a plurality of sub-components 611 for locating on the strip of fuel cell components as it passes over the top of the magazine 611. For each desired location on the strip, the pusher 609 is extended upwards in order to apply a force to a bottom sub-component in the magazine, thereby translating a top sub-component in the magazine to the second position against the strip such that the adhesive on the strip can join the sub-component 611 to the strip. The pusher 609 can then be retracted such that the second sub-component 611 from the top of the stack in the magazine can be moved away from the sub-component that has been joined to the strip. In this way, the strip can be conveniently indexed on without engaging with the next sub-component 611 in the magazine.

The sub-component 611 that is applied by the bottom application mechanism may be one or more manifold seals, a corrugated cathode plate, or any other component, in some examples a relatively rigid component such as a metallic component.

Using such a bottom application mechanism can avoid a need for pick and place handling of the strip of fuel cell components, which can be particularly advantageous in examples where the strip has delicate components that could be damaged by such pick and place operation. Also beneficially, control of the position of the strip of fuel cell components and the sub-components 611 can be maintained such that a more accurately assembled fuel cell stack can be achieved.

FIG. 6b illustrates a view from below of the bottom application mechanism of FIG. 6a engaging with a strip of fuel cell components. The top view in FIG. 6d shows a sub-component 631 in a first position that is spaced apart from a sub-component receiving portion 632 of the strip of fuel cell components. The bottom view in FIG. 6b shows that the sub-component 631 has been moved to the second position by a pusher 639. In the second position, the sub-component 631 is in contact with an adhesive surface (not shown) on the underside of the sub-component receiving portion 632 of the strip of fuel cell components.

Also shown in FIGS. 6b and 6d is that support block 633 is also movable between a first position (as shown in the top view) and a second position (as shown in the bottom view). The support block 633 is used to prevent the strip of fuel cell components from moving as the sub-component is applied to the strip of fuel cell components from below. In the first position the support block 633 is spaced apart from an upper surface of the strip of fuel cell components. In the second position, the support block 633 is adjacent to the upper surface of the strip. Use of such a support block can enable better adhesion to be provided between the underside of the strip and the sub-component 631 as a greater compression force can be applied to the two components.

FIG. 6c illustrates an alternative assembly apparatus that comprises a bottom application mechanism, which in this example is a pusher 658. In this example, instead of the sub-components being provided in a magazine, as in FIGS. 6a and 6b , the sub-components 651 are provided to a second position for joining to the strip of fuel cell components 652 by a preformed pocketed tape 660. The tape is labelled with reference 660′ in FIG. 6c when it is loaded with a sub-component 651 and is labelled with reference 660″ after the sub-component 651 has been removed. Such pocketed tape 660 is known in the art and can be advantageous as it can be used to accurately align the sub-components for subsequent adhesive pick-off.

In FIG. 6c , a component application mechanism is provided for moving a sub-component 651 from a first position that is that is spaced apart from the strip of fuel cell components (the four sub-components 651 that are furthest left in FIG. 6c are in the first position) to a second position in which the sub-component 651 is in contact with the underside of the strip of fuel cell components 652 (the sub-component 651 that is above the pusher 658 in FIG. 6c ). The component application mechanism in this example includes both the pusher 658, as described above, and a mechanism for laterally indexing the pocketed tape 660 from left to right. Alternatively, the mechanism can be considered as just the pusher 658 such that the sub-component 651 is in the first position when it is between the pusher 658 and the strip 652, but before the pusher 658 has moved the sub-component 651 into contact with the strip 652. Either way, the component application mechanism is configured to apply a force to a sub-component that is located in a pocketed tape in order to translate the sub-component to the second position.

Also shown in FIG. 6c is an optional cover tape 661 that can maintain the sub-components in a desired location in the pocketed tape 660 as it is transferred to the pusher 658. The cover tape 663 can be rolled onto a take-up spool 663 before the associated sub-component 651 is put into the second position for joining to the strip 652.

The combination of the production line 600 and the features of the strip of fuel cell component described previously reduces the physical space required to build a fuel cell stack, enables a significant amount of automation to be provided, and can improve the reproducibility and accuracy of the construction of a fuel cell stack.

The conveyor 604 can deposit fuel cells 612 formed by the application mechanisms 608, 610 into a case 614. The fuel cells 612 may be aligned by a process of self-alignment in the case 614 such that a first surface of each of the fuel cells is properly aligned. The first surface of each of the fuel cells in the stack can face in the same direction as the same first surfaces of the fuel cells when they are laid flat in the strip.

It will be appreciated that any feature of an embodiment described herein may be combined with a feature or features of any other embodiment where it is practicable to do so. For example, the production line of FIG. 6 could be used with a plurality of strips of partial fuel cell components such as the two that are shown in FIG. 5.

FIG. 7 illustrates a method of assembling a fuel cell stack. The method comprises a first step 701 of folding a strip of fuel cell components in order to locate a plurality of fuel cell components at a build position. The method also comprises an optional second step 702 of removing at least a portion of the support structure from the plurality of fuel cell components at the build position. Removing at least a portion of the support structure from the plurality of fuel cell components at the build position may comprise a third step 703 of leaving a portion of the support structure connected to the plurality of fuel cell components.

The remaining portion of the support structure can provide for an electrical connection to be made to the stack. In this way, the support structure can both hold fuel cell components during construction of the fuel cell stack and provide electrical connections to the stack.

FIG. 8 illustrates a method of assembling a fuel cell stack. The method comprises a first step 801 of indexing a strip of fuel cell components that comprise an indexing structure in order to locate a fuel cell component at a build position. The use of the indexing structure allows for a simplified method of assembling a fuel cell stack. The use of the indexing structure may also allow for the more accurate or reproducible placement of fuel cell stack components at the build position.

The method also comprises an optional second step 802 of removing the indexing structure from the fuel cell component at the build position.

The method may also comprise a third step 803 and a fourth step 804. The indexing structure of the fuel cell stack can comprise a lateral fold region between adjacent fuel cell components. At the third step 803, the indexing structure can be folded at the lateral fold regions in order to locate a plurality of fuel cell components at the build position. At the fourth step 804, the indexing structure can be removed from the plurality of fuel cell components at the build position. The removal of the indexing structure may allow for the final dimensions of the fuel cell stack to be reduced.

FIG. 9 illustrates a method of assembling a fuel cell stack. The method comprises a first step 901 of locating a first strip of partial fuel cell components over a second strip of partial fuel cell components. The first strip and second strip together may define a plurality of fuel cells.

The method continues with fan folding the first and second strips of partial fuel cell components together in order to assemble a fuel cell stack at step 902.

The method of FIG. 9 provides a convenient, accurate and reproducible means of assembling a fuel cell stack.

FIGS. 10a to 10e illustrate a strip of fuel cell components 1000 and apparatus for assembling a fuel cell from the strip of fuel cell components 1000. In particular, the strip 1000 includes a first sub-component 1002 that is rotatably connected to a second sub-component 1004 about a pivot 1006. The first sub-component 1002 is movable about the pivot 1006 between a first position that is parallel with a plane of the strip (as shown in FIGS. 10a and 10b ), a second position that is out of the plane of the strip (as shown in FIG. 10c ), and a third position, which is different to the first position, that is parallel with the plane of the strip (as shown in FIGS. 10d and 10e ). In this way, a fuel cell can conveniently be assembled by folding the first sub-component 1002 back onto the second component 1004, as described below.

FIG. 10a shows the strip of fuel cell components 1000. The strip 100 comprises first sub-components 1002 and second sub-components 1004 alternately provided along the length of the strip 1000. The strip 1000 in this example also includes a support structure 1008 that is coupled directly to each of the second sub-components 1004. Each first sub-component 1002 is rotatably connected to an adjacent second subcomponent 1004 along a first transverse edge 1007. A transverse edge is one that is transverse to a longitudinal direction of the strip 1000. The first sub-components 1002 may be rotatably connected to an adjacent second subcomponent 1004 by flexible joining sections 1011 that extend from the first transverse edge 1007. In this way the joining sections 1011 define the pivot 1006. The joining sections 1011 may be mechanically weaker than the adjacent portions of the first and second sub-components. In one example the joining sections may be regions of reduced thickness compared with the first and second sub-components 1002, 1004, for example they may be scored in order to encourage rotation of the first sub-component 1002 relative to the second sub-component.

Optionally, one or more of the first sub-components 1002 may be releasably connected to an adjacent second subcomponent 1004 along a second transverse edge 1009. The second transverse edge 1009 is opposite to the first transverse edge 1007. The first transverse edges 1007 are labelled in FIG. 10a as fold lines. The second transverse edges 1009 are labelled in FIG. 10a as shear lines, as will be understood from the description of FIG. 10c below.

The first transverse edge 1007 is a trailing edge of the first sub-component 1002 in the direction of travel of the strip 1000 relative to an apparatus for assembling a fuel cell, as will be described below. Similarly, the second transverse edge 1009 is a leading edge of the first sub-component 1002.

The first sub-components 1002 are shown in FIG. 10a in the first potion in which they are parallel with the plane of the strip 1000, and also spaced apart from each adjacent second sub-component 1004 in a direction that is in the plane of the strip 1000. When the first sub-components 1002 are in the first position they may be conveniently located for transferring the strip 1000. Also, it may be convenient to directly manufacture the strip 1000 with the first sub-components 1002 in the first position using known techniques.

FIG. 10b illustrates an apparatus for assembling a fuel cell from the strip of fuel cell components 1000 shown in FIG. 10a . The strip 1000 moves through the apparatus in a direction that is in the plane of the strip 1000 and is parallel to the longitudinal axis of the strip 1112, as shown with arrow 1013 in FIG. 10 b.

The apparatus includes a first force applicator, which in this example is a pusher 1012. The pusher 1012 is configured to apply a first force to the first sub-component 1002 in a first direction 1016 that is transverse to the plane of the strip 1000 in order to move the first sub-component 1002 about the pivot 1006 from its first position (as shown in FIG. 10b ) that is parallel with the plane of the strip 1012 to its second position that is out of the plane of the strip 1012 (as shown in FIG. 10c ). The pusher 1012 shown in FIG. 10b applies a force to a lower surface of the first sub-component 1002 in an upwards direction, which is an example of a direction that is transverse to the plane of the strip 1002. The lower surface may be referred to as an engagement surface of the first sub-component. In this way, the first sub-component 1002 is rotated about the second sub-component 1004 such that it extends out of the plane of the strip 1000 as shown in FIG. 10c . It will be appreciated that in other examples the first force applicator could be a component that pulls the first sub-component 1002 from its first position to its second position.

In this example, the apparatus also includes a separator 1016 that is configured to separate the second transverse edge 1009 of a first sub-component 1002 from the neighbouring second subcomponent 1004 before the first sub-component 1002 is moved from its first position to its second position. As shown in FIGS. 10b and 10c , the separator 1016 is movable in a direction that is transverse to the plane of the strip 1000 in order to mechanically sever a severable joining region 1022 between the two sub-components, although it will be appreciated that any other separator could be used. In some examples, an independent separator may not be required as the action of the pusher 1012 can cause any severable joining regions 1022 associated with the second transverse edge 1003 of the first sub-component 1002 to be broken.

FIG. 10c shows the first sub-component 1002 in the second position, with its second transverse edge 1009 spaced apart from the plane of the strip 1000. In this example, the pusher 1012 has moved through an aperture in the strip that has been produced by the displacement of the first sub-component 1002 from the first position to the second position. In this way, the lower/engagement surface or second transverse edge 1009 of the first sub-component 1002 is exposed for a subsequent assembly operation that applies a second force to the first sub-component 1002 in a second direction 1018 that is parallel to the plane of the strip 1000 in order to move the first sub-component 1002 from the second position to a third position that is parallel with the plane of the strip 1000. The third position is different to the first position. This subsequent assembly operation is performed by a second force applicator, which in this example is a pair of rollers 1014. It will be appreciated from the description that follows that the second position is any position that allows the second force applicator to move the first sub-component from the second position to the third position.

FIG. 10d illustrates the strip 1000 having moved towards and through the rollers 1014 from the position shown in FIG. 10c . In this way the second force in the second direction 1018 has been applied by the top roller 1014 to the rightmost first sub-component 1002 in order to move it to the third position. In the third position, the first sub-component 1002 is parallel with the plane of the strip 1000 and overlies the second sub-component 1004 that was adjacent to its first transverse edge 1007 in the first position. In this way, the first and second sub-components 1002, 1004 are no longer spaced apart in the plane of the strip 1000, as they were in the first position as shown in FIG. 10 a.

Use of one or more rollers 1014 can be advantageous as it causes the first sub-component 1002 to be progressively laid down on the second sub-component 1004, which can provide a progressive wet-out or progressive peel-off. That is, the rotation of the roller 1014 can be used to gradually increase the contact area between the first sub-component 1002 and the second sub-component 1004, with the increased contact area growing in the second direction 1018 from a transverse edge of the first sub-component 1002. This can reduce the likelihood that any air bubbles are caught between the sub-components 1002, 1004 as they should be pushed out as the first sub-component 1002 is gradually laid down. Similarly the likelihood of any wrinkles forming in the first sub-component 1002 can be recued.

FIG. 10e illustrates a strip 1000 in which all of the first sub-components 1002 in the strip 1000 have been moved to their third positions. In some examples, a complete fuel cell may be provided by each combination of first and second sub-components as shown in FIG. 10 e.

FIGS. 11a to 11e illustrate schematically the operation of a component transfer mechanism 1100 for transferring a fuel cell sub-component 1110 to a substrate, which in this example is a strip of fuel cell components 1112. The component transfer mechanism 1100 includes a rotatable roller 1102 and a transfer tape 1104 that passes around the roller 1102 and is held in tension such that rotation of the roller 11102 results in movement of the transfer tape 1104. The transfer tape 1104 defines an inner surface 1106 for contacting the roller 1102 and an opposing outer surface 1108. The outer surface 1108 of the transfer tape 1104 is configured to carry a fuel cell sub-component 1110 for placing on the strip of fuel cell components 1112. The sub-component 1110 may be releasably attached to the transfer tape 1104 by adhesive.

In this example, the sub-component 1110 is a laminate layer comprising a gas diffusion layer (GDL), a first layer of catalyst, an electrode membrane and a second layer of catalyst. The two catalyst layers and the electrode membrane can be referred to together as a membrane electrode assembly (MEA) comprising the electrode. The laminate layer is to be positioned within a gasket in the strip 1112 such that fluid within the laminate layer is kept inside the laminate layer.

The component transfer mechanism 1100 is movable relative to the strip 1112 in a first direction 1114 that is transverse to the plane of the strip 1112 in order to move the component transfer mechanism 1100 either towards or away from the strip 1112. The component transfer mechanism 1100 can be moved between a raised position in which the transfer tape 1104 on the roller 1102 is spaced apart from the strip 112 as shown in FIG. 11a , and a component transfer position as will be described below with reference to FIG. 11 d.

The roller 1102 can also be rotatably driven, in some examples simultaneously, such that the transfer tape 1104 moves around the roller 1102 and correspondingly the sub-component 1110 moves towards the roller 1102 such that the sub-component 1110 on the transfer tape 1104 is located in between the roller 1102 and the strip 1112 when the component transfer mechanism is in the component transfer position. The roller 1102 can be driven either directly or indirectly. As shown in FIG. 11b , the roller 1102 has been rotated such that the sub-component 1110 has moved downwards such that it is on a region of the transfer tape 1104 that is adjacent to the roller 1102 yet is still transverse to the plane of the strip 1112. Also as shown in FIG. 11b , the component transfer mechanism 1100 has been moved in the first direction 1114 such that the roller 1102 is closer to the strip 1112.

FIG. 11c shows the component transfer mechanism 1100 in a position that is approaching the component transfer position, which is shown in FIG. 11d . In FIG. 11c , it can be seen that the plane of the sub-component 1100 is tending towards the plane of the strip 1112 as the sub-component 1108 moves around the roller 1102 as it continues to rotate. In this example the roller 1102 has a radius that is sufficiently small in order to cause a transverse edge of the sub-component 1100 to be detached from the transfer tape 1104 as it passes around the roller 1102. That is, a leading edge 1116 of the sub-component 1110 moves away from the transfer tape 1104 as the sub-component 1110 moves around the radius of the roller 1102. This is because the tack strength of the adhesive between the sub-component 1110 and transfer tape 1104 is not great enough to act against the rigidity of the sub-component 1110 and bend the sub-component 1110 for the specific radius of the roller 1102. The adhesive that is used between the sub-component 1110 and the transfer tape 1104 may have preferential release characteristics; for example the adhesive may have a higher tack strength in tension than in peel. This can advantageously assist in detaching the sub-component 1110 from the transfer tape 1104 at an appropriate time, and in an appropriate location, for attaching it to the strip 1112.

In this example, the strip 1112 has a region of exposed adhesive 1020 that will be contacted by the sub-component 1110 when it is in the component transfer position.

As the component transfer mechanism 1100 arrives at the component transfer position as shown in FIG. 11d , due to the continued rotation and lowering of the roller 1102, the sub-component 1110 is placed adjacent to the strip 1112 and is orientated in the same plane as the strip 1112. The tack strength of the adhesive between the strip 1112 and the sub-component 1110 is stronger than the tack strength of the adhesive between the sub-component 1110 and the transfer tape 1104 when the component transfer mechanism 1100 is in the component transfer position. This may in part be due to a reduced contact area between the sub-component 1110 and the transfer tape because of the curvature of the roller 1102 and the stiffness of the sub-component 1110.

FIG. 11e shows the component transfer mechanism having been moved away from the strip 1112 such that the sub-component 1110 has been left in position on the strip 1112.

The strip 1112 can continuously or non-continuously be moved in a second direction 1118 relative to the roller 1102 in order to assist with the detachment of the sub-component 1110 from the transfer tape 1104 and/or to move the roller 1102 to a different place on the strip 1112 for depositing a subsequent sub-component. The second direction 1118 is parallel to a longitudinal axis of the strip 1112. In this way, the rotation of the roller 1102 and movement of the roller 1102 in the first direction can be repeated for subsequent placement operations of sub-components.

Progressively laying down the sub-component 1110 in this way can be advantageous as it can provide a progressive wet-out or progressive peel-off, as described above.

In some examples the speed of the transfer tape 1104 around the roller 1102 may be faster than the speed of the strip 1112 relative to the component transfer mechanism in the second direction 1118. In this way, the resulting relative motion between the sub-component 1110 and the strip 1112 in the second direction 1118 can assist with correctly locating the sub-component 1110 in a desired position. In the example that the sub-component is a laminate layer that is to be fitted snugly into an aperture in a gasket, the motion of the laminate layer relative to the gasket can cause a leading edge of the laminate layer (which may have been detached from the transfer tape 1104 due to the stiffness of the laminate layer and the radius of the roller 1102) to abut an inside wall of the aperture in the gasket such that the remaining portion of the laminate layer fits tightly into the aperture. This can be particularly advantageous for fuel cells as any gaps between the laminate layer and gasket can enable a fuel cell fluid (such as hydrogen) to bypass an active area of the fuel cell, thereby degrading performance.

The assembly method described with reference to FIGS. 11a to 11e may be referred to as pitch hopping. Such an assembly method can be advantageous as control over the location of the components can be retained at all times during the assembly, and therefore complicated and costly location identification techniques do not have to be used to properly align the components. In turn, this can lead to a more accurately assembled fuel cell.

FIG. 12 illustrates a method of transferring a fuel cell sub-component to a substrate using a component transfer mechanism such as the one described and illustrated with reference to FIGS. 11a to 11e . In particular, the component transfer mechanism may comprise at least a rotatable roller; and a transfer tape that passes around the roller and is held in tension such that rotation of the roller results in movement of the transfer tape. As above, the transfer tape defines an outer surface configured to carry the fuel cell sub-component.

At step 1202 the method comprises moving the component transfer mechanism relative to the substrate in a first direction, which is transverse to a plane of the substrate, between a component transfer position in which the transfer tape on the roller is adjacent the substrate and a raised position in which the transfer tape on the roller is spaced apart from the substrate.

The method also includes, at step 1204, rotating the rotatable roller such that the sub-component on the transfer tape is located in between the roller and the substrate when the component transfer mechanism is in the component transfer position. In some examples steps 1202 and 1204 may be performed at the same time.

FIG. 13 illustrates a method of assembling a fuel cell from a strip of fuel cell components such as the one described and illustrated with reference to FIGS. 10a to 10e . The strip of fuel cell components may comprise at least a first sub-component that is rotatably connected to a second sub-component about a pivot.

At step 1302, the method includes applying a first force to the first sub-component in a first direction that is transverse to the plane of the strip in order to move it from a first position that is parallel with a plane of the strip to a second position that is out of the plane of the strip. This movement may be about a pivot. Subsequently at step 1304; the method comprises applying a second force to the first sub-component in a second direction that is parallel to the plane of the strip in order to move the first sub-component from the second position to a third position that is parallel with the plane of the strip and is different to the first position. This movement may also be about the pivot.

FIG. 14 illustrates a method of assembling a fuel cell comprising that can be performed by the apparatus illustrated in FIGS. 6a to 6c . The method includes, at step 1402, moving a strip of fuel cell components in a first direction that is parallel to a longitudinal axis of the strip of fuel cell components in order to locate a sub-component receiving portion of the strip at a build point. At step 1402, the method includes applying a sub-component to an underside of the sub-component receiving portion of the strip at the build-point.

It will be appreciated that any discussion of specific directions of forces or movement that are discussed in this document includes forces and directions that have a component in the direction indicated. Such forces and directions may also have components in other directions. 

The invention claimed is:
 1. A strip of fuel cell components comprising: a plurality of fuel cell components spaced apart in a first direction; an indexing structure connected to the plurality of fuel cell components, the indexing structure configured to define the position of one of the plurality of fuel cell components in the first direction; and, wherein the indexing structure comprises a different material to the plurality of fuel cell components, and wherein the indexing structure is releasably or severably connected to the plurality of fuel cell components.
 2. The strip of fuel cell components of claim 1 wherein the plurality of fuel cell components comprises a plurality of fuel cell assemblies, each fuel cell assembly comprising a fuel cell plate.
 3. The strip of fuel cell components of claim 2, wherein the plurality of fuel cell components comprises a first end plate, a plurality of fuel cell assemblies and a second end plate, in that order extending in the first direction.
 4. The strip of fuel cell components of claim 1, wherein the indexing structure comprises a plurality of indentations or holes for engaging with an indexor in order to define the position of one of the plurality of fuel cell components.
 5. The strip of fuel cell components of claim 1, wherein the indexing structure is connected to the plurality of fuel cell components by at least one spot weld.
 6. The strip of fuel cell components of claim 1, wherein the indexing structure comprises a lateral fold region between adjacent fuel cell components.
 7. A strip of fuel cell components comprising: a plurality of fuel cell components spaced apart in a first direction; an indexing structure connected to the plurality of fuel cell components, the indexing structure configured to define the position of one of the plurality of fuel cell components in the first direction; and, wherein the indexing structure comprises a different material to the plurality of fuel cell components; and, wherein the indexing structure comprises a plurality of electrically conductive tracks that are insulated from one another.
 8. A fuel cell stack having a folded strip of fuel cell components comprising a plurality of fuel cell components spaced apart in a first direction; an indexing structure connected to the plurality of fuel cell components, the indexing structure configured to define the position of one of the plurality of fuel cell components in the first direction; and, wherein the indexing structure comprises a different material to the plurality of fuel cell components.
 9. A method of assembling a fuel cell stack, the method comprising: indexing the strip of fuel cell components according to claim 1 in order to locate a fuel cell component at a build position.
 10. The method of claim 9, further comprising removing the indexing structure from the fuel cell component at the build position.
 11. The method of claim 9, wherein the indexing structure comprises a lateral fold region between adjacent fuel cell components, the method further comprising: folding the indexing structure at the lateral fold regions in order to locate a plurality of fuel cell components at the build position. 